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How to simplify a given boolean expression with many variables (>10) so that the number of occurrences of each variable is minimized?

In my scenario, the value of a variable has to be considered ephemeral, that is, has to recomputed for each access (while still being static of course). I therefor need to minimize the number of times a variable has to be evaluated before trying to solve the function.

Consider the function

f(A,B,C,D,E,F) = (ABC)+(ABCD)+(ABEF)

Recursively using the distributive and absorption law one comes up with

f'(A,B,C,E,F) = AB(C+(EF))

I'm now wondering if there is an algorithm or method to solve this task in minimal runtime.

Using only Quine-McCluskey in the example above gives

f'(A,B,C,E,F) = (ABEF) + (ABC)

which is not optimal for my case. Is it save to assume that simplifying with QM first and then use algebra like above to reduce further is optimal?

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The Google term is "fanout minimization". There are algorithms to design fanout-free circuits where every literal does not occur more than once. However, this is only possible for special boolean expressions. –  Axel Kemper Aug 27 '13 at 20:35

3 Answers 3

up vote 0 down vote accepted

Try Logic Friday from http://sontrak.com

It features multi-level design of boolean circuits.

For your example, input and output look as follows:

enter image description here

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I'm looking for an algorithm or method since i need to implement it into code. The result Z as shown above is not optimal for my case as A and B are evaluated twice –  user2722968 Aug 28 '13 at 18:21
Look at the circuit depicted in the image. A general algorithm beyond heuristics is not known to me. You might ask Google for "Reduced Binary Decision Diagrams". en.wikipedia.org/wiki/Binary_decision_diagram –  Axel Kemper Aug 28 '13 at 20:33
Reading papers on fanout and bdds, this seems to be the general answer I was looking for, thanks. –  user2722968 Aug 29 '13 at 18:52
@user2722968 If you plan to implement this yourself you want to (at the very least) read chapter 8 in Synthesis and Optimization of Digital Circuits by Giovanni De Micheli. The theory of multi-level minimization is far less simple than that of two-level minimization. –  Respawned Fluff Feb 13 at 6:42
Also chapter 11 in Logic Synthesis and Verification Algorithms by Hachtel and Somenzi. –  Respawned Fluff Feb 13 at 7:24

I usually use Wolfram Alpha for this sort of thing.

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Karnaugh map will be a good starting point for you.

The Karnaugh map, also known as the K-map, is a method to simplify boolean algebra expressions. Maurice Karnaugh introduced it in 1953 as a refinement of Edward Veitch's 1952 Veitch diagram. The Karnaugh map reduces the need for extensive calculations by taking advantage of humans' pattern-recognition capability. It also permits the rapid identification and elimination of potential race conditions.

enter image description here

There are a lot of automated solvers available. Please see example here:

enter image description here

You can also check: http://sourceforge.net/projects/k-map/

Another implementation with a source code is available here: Minimizing Boolean Functions

It is pretty straightforward:

$ java -cp Minimize.zip Minimize "aa'+b1"
Finding One Minimization
Minterm Numbers:  [1,3]
Reduced ab and a'b to b in pass 1.
Unable to reduce b in pass 2
Minterm 1 is covered by 1 prime implicant.
Minterm 3 is covered by 1 prime implicant.
Expression:       a*a'+b*1
Sum of products:  a'b + ab
Prime implicants: [ b: a'b, ab ]
Minimized:        b
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k-maps will not arrive at the form I need because the result is flat. Nested functions are favored over repeated variables. In your example, BC+BD should be written as B & (C | D) –  user2722968 Sep 7 '13 at 5:58
Indeed, K-maps do two-level optimization. He wants multi-level optimization which is a more difficult topic. –  Respawned Fluff Feb 13 at 7:02

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